Difference between revisions of "Principal ideal"
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| − | The left principal ideal $L(\alpha)$ of a ring $ | + | An [[ideal]] (of a [[ring]], algebra, [[semi-group]], or [[lattice]]) generated by one element $\alpha$, i.e. the smallest ideal $L(\alpha)$ containing the element $\alpha$. |
| + | |||
| + | ===Rings=== | ||
| + | The left principal ideal $L(\alpha)$ of a ring $A$ contains, in addition to the element $\alpha$ itself, also all the elements | ||
$$k\alpha+n\alpha$$ | $$k\alpha+n\alpha$$ | ||
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$$n\alpha+t\alpha+\alpha s+\sum _{ i }{ [(k_{ i }\alpha)l_{ i }+k_{ i }^\prime (\alpha l_{ i }^\prime )] } $$ | $$n\alpha+t\alpha+\alpha s+\sum _{ i }{ [(k_{ i }\alpha)l_{ i }+k_{ i }^\prime (\alpha l_{ i }^\prime )] } $$ | ||
| − | where $k,t,s,k_{i},k_{i}^{\prime},l_{i},l_{i}^{\prime}$ are arbitrary elements of $K$ and $n\alpha=\alpha+\dots +\alpha$ $ | + | where $k,t,s,k_{i},k_{i}^{\prime},l_{i},l_{i}^{\prime}$ are arbitrary elements of $K$ and $n\alpha=\alpha+\dots +\alpha$ ($n$ terms, $n\in\Z$). If $A$ is a ring with a unit element, in particular, for an algebra $A$ over a field, the term $n\alpha$ may be omitted: |
| + | $$ | ||
| + | L(a)=A\alpha,\qquad R(a)=\alpha A,\qquad J(\alpha)=A\alpha A\ . | ||
| + | $$ | ||
| − | $$ | + | ====Comments==== |
| + | Let $A$ be an [[integral domain]] with [[field of fractions]] $K$. A principal fractional ideal of $A$ is an $A$-submodule of $K$ of the form $Ar$ for some $r\in K$. | ||
| + | ===Semigroups=== | ||
In a semi-group $S$ one also has left, right and two-sided ideals generated by an element $\alpha$, and they are equal, respectively, to | In a semi-group $S$ one also has left, right and two-sided ideals generated by an element $\alpha$, and they are equal, respectively, to | ||
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where $S^1$ is the semi-group coinciding with $S$ if $S$ contains a unit, and is otherwise obtained from $S$ by external adjunction of a unit. | where $S^1$ is the semi-group coinciding with $S$ if $S$ contains a unit, and is otherwise obtained from $S$ by external adjunction of a unit. | ||
| + | ===Lattices=== | ||
The principal ideal of a lattice $L$ generated by an element $\alpha$ is identical with the set of all $x$ such that $x \le \alpha$; it is usually denoted by $\alpha^\Delta$,$[{\alpha}]$, or $[{0,\alpha}]$ if the lattice has a zero. Thus, | The principal ideal of a lattice $L$ generated by an element $\alpha$ is identical with the set of all $x$ such that $x \le \alpha$; it is usually denoted by $\alpha^\Delta$,$[{\alpha}]$, or $[{0,\alpha}]$ if the lattice has a zero. Thus, | ||
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====Comments==== | ====Comments==== | ||
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| − | |||
Let $L$ be a lattice. Dual to the principal ideal generated by $\alpha \in L$ one has the principal dual ideal or principal filter determined by $\alpha$, which is the set $[\alpha)=\left\{ y\in L:\alpha \le y \right\} $. The principal ideal in $L$ determined by $\alpha$ is also denoted (more accurately) by $[\alpha)$. | Let $L$ be a lattice. Dual to the principal ideal generated by $\alpha \in L$ one has the principal dual ideal or principal filter determined by $\alpha$, which is the set $[\alpha)=\left\{ y\in L:\alpha \le y \right\} $. The principal ideal in $L$ determined by $\alpha$ is also denoted (more accurately) by $[\alpha)$. | ||
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====References==== | ====References==== | ||
| − | + | {| | |
| + | |- | ||
| + | |valign="top"|{{Ref|Be}}||valign="top"| L. Beran, "Orthomodular lattices", Reidel (1985) pp. 4ff | ||
| + | |- | ||
| + | |valign="top"|{{Ref|Gr}}||valign="top"| G. Grätzer, "Lattice theory", Freeman (1971) | ||
| + | |- | ||
| + | |valign="top"|{{Ref|Ku}}||valign="top"| A.G. Kurosh, "Lectures on general algebra", Chelsea (1963) pp. 78; 86; 162 (Translated from Russian) | ||
| + | |- | ||
| + | |valign="top"|{{Ref|Ly}}||valign="top"| E.S. Lyapin, "Semigroups", Amer. Math. Soc. (1963) pp. Chapt. IV, Sect. 3 (Translated from Russian) | ||
| + | |- | ||
| + | |} | ||
| + | |||
| + | [[Category:General algebraic systems]] | ||
Latest revision as of 20:54, 28 November 2014
An ideal (of a ring, algebra, semi-group, or lattice) generated by one element $\alpha$, i.e. the smallest ideal $L(\alpha)$ containing the element $\alpha$.
Rings
The left principal ideal $L(\alpha)$ of a ring $A$ contains, in addition to the element $\alpha$ itself, also all the elements
$$k\alpha+n\alpha$$
the right principal ideal $R(\alpha)$ contains all the elements
$$\alpha k+n\alpha$$
and the two-sided principal ideal $J(\alpha)$ contains all elements of the form
$$n\alpha+t\alpha+\alpha s+\sum _{ i }{ [(k_{ i }\alpha)l_{ i }+k_{ i }^\prime (\alpha l_{ i }^\prime )] } $$
where $k,t,s,k_{i},k_{i}^{\prime},l_{i},l_{i}^{\prime}$ are arbitrary elements of $K$ and $n\alpha=\alpha+\dots +\alpha$ ($n$ terms, $n\in\Z$). If $A$ is a ring with a unit element, in particular, for an algebra $A$ over a field, the term $n\alpha$ may be omitted: $$ L(a)=A\alpha,\qquad R(a)=\alpha A,\qquad J(\alpha)=A\alpha A\ . $$
Comments
Let $A$ be an integral domain with field of fractions $K$. A principal fractional ideal of $A$ is an $A$-submodule of $K$ of the form $Ar$ for some $r\in K$.
Semigroups
In a semi-group $S$ one also has left, right and two-sided ideals generated by an element $\alpha$, and they are equal, respectively, to
$$L(\alpha)=S^1\alpha,\qquad R(\alpha)=\alpha S^1,\qquad L(\alpha)=S^1\alpha S^1,$$
where $S^1$ is the semi-group coinciding with $S$ if $S$ contains a unit, and is otherwise obtained from $S$ by external adjunction of a unit.
Lattices
The principal ideal of a lattice $L$ generated by an element $\alpha$ is identical with the set of all $x$ such that $x \le \alpha$; it is usually denoted by $\alpha^\Delta$,$[{\alpha}]$, or $[{0,\alpha}]$ if the lattice has a zero. Thus,
$$\alpha^{ \Delta }=\alpha L=\{ { \alpha x:x\in L }\} .$$
In a lattice of finite length all ideals are principal.
Comments
Let $L$ be a lattice. Dual to the principal ideal generated by $\alpha \in L$ one has the principal dual ideal or principal filter determined by $\alpha$, which is the set $[\alpha)=\left\{ y\in L:\alpha \le y \right\} $. The principal ideal in $L$ determined by $\alpha$ is also denoted (more accurately) by $[\alpha)$.
A partially ordered set is a complete lattice if and only if it has a zero and every ideal in $L$ is principal.
References
| [Be] | L. Beran, "Orthomodular lattices", Reidel (1985) pp. 4ff |
| [Gr] | G. Grätzer, "Lattice theory", Freeman (1971) |
| [Ku] | A.G. Kurosh, "Lectures on general algebra", Chelsea (1963) pp. 78; 86; 162 (Translated from Russian) |
| [Ly] | E.S. Lyapin, "Semigroups", Amer. Math. Soc. (1963) pp. Chapt. IV, Sect. 3 (Translated from Russian) |
Principal ideal. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Principal_ideal&oldid=24901